Dynamic random access memory having sense amplifier control circuit supplied with external sense amplifier activating signal

ABSTRACT

The present invention relates to a high-speed data transmission system for efficiently transmitting large amounts of data within short periods of time. A DRAM comprises at least a memory cell, sense amplifiers, a /RAS signal input, a word line (WL) boost signal generator, a sense amplifier control signal-generator, and a sense amplifier drive signal-generator, wherein the memory cell is constituted by a plurality of banks, the sense amplifiers are provided in a corresponding plurality of numbers, the sense amplifier control signal-generator are provided in a plurality of numbers to correspond to the plurality of banks, and provision is made of external sense amplifier activating signal terminals which are connected to the sense amplifier control signal-generator in order to activate the sense amplifiers independently of the /RAS signal.

CROSS-REFERENCE TO RELATED APPLICATION

The present application is related to U.S. application Ser. No.08/186,609 dated Jan. 26, 1994 in which one of the assignees is the sameas the assignee of the present application.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a sense amplifier control circuit andto a sense amplifier control method. More specifically, the inventionrelates to technology for controlling the activation of sense amplifiersin a dynamic random access memory (hereinafter referred to as DRAM)having a bank system.

2. Description of the Related Art

The trend toward higher operation speeds of arithmetic units (CPUs) hasurged manufacturers to develop DRAM technology for transmitting data athigh speeds.

In a conventional high-speed data processing and transmitting system, ingeneral, a word line (WL) in the DRAM is activated by a row addressstrobe signal (hereinafter referred to as /RAS signal), and a senseamplifier activating signal activates the sense amplifier in synchronismwith the /RAS signal after a suitable delay time by which the word line(WL) assumes a sufficiently large level due to the /RAS signal.

FIG. 12 is a block diagram explaining a circuit for executing a functionfor activating word lines (WL) in the DRAM and a function for activatingsense amplifiers according to a prior art. In FIG. 12, the senseamplifier control circuit 100 is constituted by a /RAS signal processingcircuit 1 that inputs a /RAS signal, a word line (WL) boostsignal-generating circuit 2 which receives an output from the /RASsignal processing circuit 1 and outputs a control signal to a word line(WL) predecoder circuit 3 in response to the /RAS signal, a word line(WL) main decoder circuit 4 which receives an output from the word line(WL) predecoder circuit 3 and selects activation or de-activation of apredetermined word line (WL), a sense amplifier controlsignal-generating means 5 which generates a control signal forcontrolling the sense amplifier in response to the output of the wordline (WL) boost signal-generating circuit 2, a bit line resetsignal-generating circuit 6 that resets a bit line in response to anoutput of the sense amplifier control signal-generating means 5, and asense amplifier drive signal-generating means 7 which outputs a senseamplifier activating signal. The basic operation of the sense amplifiercontrol circuit 100 is as described below. That is, as shown in thewaveform diagram of FIG. 13, the selected word line (WL) is activated atthe down edge of the /RAS signal, and the sense amplifier drivesignal-generating means 7 outputs an internal sense amplifier activatingsignal after the passage of a predetermined delay time that is set bytaking into consideration the time by which the above word line (WL) israised sufficiently to activate the sense amplifier.

In order to read the data in the sense amplifier, the bit line must havebeen reset prior to activating the word line (WL). Even in the priorart, therefore, a reset signal for resetting the bit line is output fromthe bit line reset signal-generating circuit 6 in synchronism with thebreak of the /RAS signal.

Then, as the /RAS signal rises, the word line (WL) is de-activated insynchronism therewith, and the sense amplifier is de-activated insynchronism therewith, whereby the bit line reset signal is no longerproduced.

That is, according to the prior art, activation of the word line (WL)and activation of the sense amplifier are controlled by the same /RASsignal at all times. Therefore, when the /RAS signal is de-activated,both the word line (WL) and the sense amplifier are de-activated, and,hence, the data that is once selected is readily output in response to asuitable column address signal or is erased as the /RAS signal isde-activated. Even when it is desired to read related data, therefore,the row and column must be selected again using another /RAS signal,requiring extended periods of time for transmitting the data.

As the arithmetic units are operated at higher speeds, the above problembecomes important. When it is attempted to realize a high-speed DRAMtechnology, the above-mentioned conventional data transmissiontechnology is no longer useful.

SUMMARY OF THE INVENTION

The object of the present invention is to provide a high-speed datatransmission system which efficiently transmits large amounts of datawithin short periods of time by solving the problem inherent in theprior art. More concretely speaking, the present invention provides acircuit for controlling sense amplifiers and a method of controllingsense amplifiers for realizing the aforementioned high-speed datatransmission system.

In order to accomplish the above-mentioned object, the present inventionemploys technical constitution that is described below. That is,according to a first embodiment of the present invention, there isprovided a dynamic random access memory (DRAM) comprising: a pluralityof memory cells selected by the word lines and the bit lines; senseamplifiers connected to each one of the bit lines; a word line (WL)boost signal-generating circuit for actuating at least one of the wordlines, in response to an input of a row address strobe (/RAS) signal;and a sense amplifier control signal-generating circuit to control thesense amplifier so as to actuate or deactuate thereof, in response tothe row address strobe (/RAS) signal and an external sense amplifieractivating signal output from an external sense amplifier activatingsignal generating circuit.

According to a second embodiment of the present invention, there isprovided a dynamic random access memory (DRAM) comprising: a pluralityof memory cells selected by the word lines and the bit lines; senseamplifiers connected to each one of the bit lines a word line (WL) boostsignal-generating circuit for actuating at least one of the word linesby one shot pulse in synchronism with the rising and breaking edges ofeach one of a plurality of row address strobe (/RAS) signals; and asense amplifier control signal-generating circuit to control the senseamplifier so as to actuate or deactuate thereof, in synchronism with therow address strobe (/RAS) signals.

According to a third embodiment of the present invention, there isprovided a dynamic random access memory (DRAM) comprising: a pluralityof memory cells selected by the word lines and the bit lines; senseamplifiers connected to each one of the bit lines; a word line (WL)boost signal-generating circuit for actuating at least one of the wordlines by a one shot pulse in synchronism with the rising and breakingedges of each one of a plurality of row address strove (/RAS) signals;and a sense amplifier control signal-generating circuit is soconstituted as to activate the sense amplifiers in synchronism with thebank address signals that are derived from the row address strobe (/RAS)signal.

According to a specific feature of the first embodiment of the presentinvention, there is provided a sense amplifier control circuit in adynamic random access memory (DRAM) which comprises at least a memorycell means, sense amplifiers, a /RAS signal input means, a word line(WL) boost signal-generating means, a sense amplifier controlsignal-generating means and a sense amplifier drive signal-generatingmeans, and which reads cell data by activating the word lines (WL) byutilizing row address strobe (/RAS) signals, wherein said memory cellmeans is constituted by a plurality of banks, said sense amplifiercontrol signal-generating means are provided in a plurality of numbersto correspond to the plurality of banks, and provision is made of anexternal sense amplifier activating signal, means which is connected tosaid sense amplifier control signal-generating means in order toactivate the sense amplifiers independently of the /RAS signals.

According to a specific feature of the second embodiment of the presentinvention, there is provided a sense amplifier control circuit in adynamic random access memory (DRAM) which comprises at least a memorycell means, sense amplifiers, a /RAS signal input means, a word line(WL) boost signal-generating means, a sense amplifier controlsignal-generating means and a sense amplifier drive signal-generatingmeans, and which reads cell data by activating the word lines (WL) byutilizing row address strobe (/RAS) signals, wherein said memory cellmeans is constituted by a plurality of banks, said sense amplifiercontrol signal-generating means are provided in a plurality of numbersto correspond to the plurality of banks, said /RAS signals are formed ina plurality of numbers to correspond to the plurality of banks, saidword line (WL) boost signal-generating means is so constituted as toactivate the word lines (WL) by one shot pulse in synchronism with therising and falling edges of the /RAS signals, and said sense amplifiercontrol signal-generating means is so constituted as to activate thesense amplifiers in synchronism with the /RAS signals.

According to a specific feature of the third embodiment of the presentinvention, there is provided a sense amplifier control circuit in adynamic random access memory (DRAM) which comprises at least a memorycell means, sense amplifiers, a /RAS signal input means, a word line(WL) boost signal-generating means, a sense amplifier controlsignal-generating means and a sense amplifier drive signal-generatingmeans, in order to read cell data by activating the word lines (WL) byutilizing row address strobe (/RAS) signals, wherein said memory cellmeans is constituted by a plurality of banks, said sense amplifiercontrol signal-generating means are provided in a plurality of numbersto correspond to the plurality of banks, said word line (WL) boostsignal-generating means is so constituted as to activate the word lines(WL) by one shot pulse in synchronism with the rising and falling edgesof the /RAS signals, and said sense amplifier control signal-generatingmeans is so constituted as to activate the sense amplifiers insynchronism with bank address signals that are derived from said /RASsignals.

In the sense amplifier control circuit in a DRAM which employs a banksystem using a plurality of banks according to the present invention asdescribed above, the circuit for activating the word lines (WL) in theDRAM is commonly used, and the word line (WL) activating function andthe sense amplifier activating function are so constituted that theywill be driven independently of each other. Therefore, the senseamplifier activating function is activated without being controlled by apredetermined /RAS signal and, as required, the sense amplifieractivating function is maintained in the activated condition to hold thenecessary data. When the same data or the data having a predeterminedrelationship to the above data are to be read out, therefore, the timefor executing the arithmetic processing can be greatly shortened.

That is, according to the present invention, the sense amplifieractivating signal means is maintained in the active condition even whenthe word lines (WL) are in the de-activated condition due to thede-activated /RAS signal. Therefore, the time can be shortened when thedata in the same bank are to be read out again, i.e., when a group ofdata that have been stored are to be read out again, enabling largeamounts of data to be transmitted at high speeds.

Furthermore, according to the present invention which uses a pluralityof banks, it is allowed to maintain a bank activated, i.e., to maintainpredetermined data while exchanging data with other banks. It is furtherallowed to extend the period for activating the sense amplifiers up to aperiod which is equal to a maximum refreshing time in the DRAM, giving amargin to the arithmetic processing operation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating a sense amplifier control circuitaccording to a first embodiment of the present invention;

FIG. 2 is a block diagram illustrating the whole constitution of thesense amplifier control circuit according to the first embodiment of thepresent invention;

FIG. 3 is a block diagram illustrating a RAS initial-stage circuit usedin the sense amplifier control circuit according to the first embodimentof the present invention;

FIG. 4 is a block diagram illustrating a sense amplifier controlsignal-generating circuit used in the sense amplifier circuit accordingto the first embodiment of the present invention;

FIGS. 5A-5F are diagrams of waveforms illustrating the operation of thesense amplifier control circuit according to the first embodiment of thepresent invention;

FIG. 6 is a block diagram illustrating the sense amplifier controlcircuit according to a second embodiment of the present invention;

FIG. 7 is a block diagram illustrating the whole constitution of thesense amplifier control circuit according to the second embodiment ofthe present invention;

FIGS. 8A-8H are diagrams of waveforms illustrating the operation of thesense amplifier control circuit according to the second embodiment ofthe present invention;

FIG. 9 is a block diagram illustrating the sense amplifier controlcircuit according to a third embodiment of the present invention;

FIG. 10 is a block diagram illustrating the whole constitution of thesense amplifier control circuit according to the third embodiment of thepresent invention;

FIGS. 11A-11J are diagrams of waveforms illustrating the operation ofthe sense amplifier control circuit according to the third embodiment ofthe present invention;

FIG. 12 is a block diagram illustrating a conventional sense amplifiercontrol circuit;

FIGS. 13A-13D are diagrams of waveforms illustrating the operation ofthe conventional sense amplifier control circuit;

FIG. 14 is a block diagram illustrating the system constitution of thesense amplifier control circuit according to the first embodiment of thepresent invention;

FIG. 15 is a block diagram illustrating the system constitution of thesense amplifier control circuit according to the second embodiment ofthe present invention; and

FIG. 16 is a block diagram illustrating the system constitution of thesense amplifier circuit according to the third embodiment of the presentinvention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the sense amplifier control circuit according to thepresent invention will now be described in detail with reference to thedrawings.

In order to develop a new data transmission system which meets thedemand by improving defects inherent in the above-mentioned prior art, anew technology has been proposed by incorporating a bank system in thedata transmission system that uses sense amplifiers of a conventionalDRAM.

Employment of the bank system makes it possible to execute the operationof reading/writing large amounts of data within short periods of time.

That is, large amounts of data are output in parallel within shortperiods of time, and are subjected to the parallel-serial conversion totransmit the data at high speeds. Here, employment of the bank systemmakes it possible to execute access maintaining further improvedefficiency.

In the DRAM based upon the conventional bank system, however, the bankcontrol or the sense amplifier activation processing is carried outtogether with the word line (WL) activation processing which is basedupon the /RAS signal without any degree of freedom and, hence, making itdifficult to efficiently access large amounts of data.

According to the present invention in which the word line (WL)activating function and the external sense amplifier activating functionoperate independently from each other as described above, the word line(WL) may be activated or de-activated depending upon the /RAS signal,but the sense amplifier is allowed to hold predetermined data for apredetermined period of time even when the word line (WL) isde-activated since the sense amplifier activating signal is capable ofmaintaining the activated condition. Therefore, when the predetermineddata is selectively read out from a given bank followed by the readingof other data from the same bank, there is no need of making access torow addresses but access can be simply made to column addresses only,making it possible to greatly shorten the access time.

A first embodiment according to the present invention will now bedescribed.

FIGS. 1 and 2 are block diagrams illustrating a sense amplifier controlcircuit 10 according to the first embodiment of the present invention.That is, in a dynamic random access memory (DRAM) which comprises atleast a memory cell means 11, sense amplifiers 12, a /RAS signal inputmeans 1, a word line (WL) boost signal-generating means 2, a senseamplifier control signal-generating means 5 and a sense amplifier drivesignal-generating means 7, in order to read cell data by activating theword lines (WL) by utilizing row address strobe (/RAS) signals, a senseamplifier control circuit wherein said memory cell means 11 isconstituted by a plurality of banks 11', 11", said sense amplifiers areprovided in a corresponding plurality of numbers 12', 12", said senseamplifier control signal-generating means 5 are provided in a pluralityof such amplifiers 5', 5" to correspond to the plurality of banks 11',11", and provision is made of external sense amplifier activating signalterminals 15', 15" which are connected to said sense amplifier controlsignal-generating means 5', 5" in order to activate the sense amplifiers12', 12" independently of the /RAS signals.

FIG. 1 is a block diagram illustrating the constitution of theabove-mentioned sense amplifier control circuit 10 according to thepresent invention, wherein the same constituent elements as those ofFIG. 12 are denoted by the same reference numerals as those of FIG. 12.

FIG. 2 is a block diagram which schematically illustrates the wholesystem constitution of the sense amplifier control circuit 10 accordingto the first embodiment of the present invention shown in FIG. 1.

In the sense amplifier control circuit 10 according to the firstembodiment of the present invention as will be comprehended from FIG. 2,a column address control circuit 16 is provided separately from that ofthe /RAS signal system, the column address control circuit 16 beingprovided, for example, with a column address signal input circuit 17 anda suitable input/output circuit (I/0 CCT) 18.

That is, as shown in FIG. 2, the sense amplifier control circuit 10according to the present invention is constituted by a RAS circuit 20, amemory circuit 11 made up of a plurality of banks 11', 11" and senseamplifiers 12', 12" corresponding to the banks 11', 11", and a columnaddress control circuit 16. The RAS circuit 20 is constituted by a RASfirst-stage circuit 13, a first sense amplifier controlsignal-generating circuit 5', a second sense amplifier controlsignal-generating circuit 5", a first row decoder 8' that controls thefirst bank 11', a first sense amplifier drive signal-generating circuit7' that controls the first sense amplifier 12', a second row decoder 8"that controls the second bank 11", and a second sense amplifier drivesignal-generating circuit 7" that controls the second sense amplifier12".

In the RAS first-stage circuit 13 in the sense amplifier control circuit10 according to the first embodiment of the present invention, there isprovided a RAS signal first-stage input circuit 1 as a /RAS signal inputmeans 1 and an external bank signal row address input terminal 14 thatdetermines which one of the plurality of banks is to be selected, andwherein an external bank signal row address signal and an output of theRAS signal first-stage input circuit 1 are input to a row address buffer27, and predetermined internal bank signals BNKX and BNKZ are outputfrom the row address buffer 27 and are separately input to the first andsecond sense amplifier control signal-generating means 5' and 5".

The external bank signal according to the present invention is anaddress signal of the bank which may be the same as the /RAS signal.

By using the external bank signal, it is allowed to latch the data of apredetermined bank and to hold the latched data for a predeterminedperiod of time irrespective of whether the /RAS signal is activated orde-activated.

The characteristic technical constitution according to the firstembodiment of the present invention resides in that provision is made ofthe first and second sense amplifier control signal-generating means 5'and 5", and the first and second sense amplifier drive signal-generatingmeans 7', 7" are selected in order that a predetermined bank isactivated by the sense amplifier control signal-generating means 5', 5"in response to the predetermined internal bank signals BNKX and BNKZ,first external sense amplifier activating signal terminal 15' and secondexternal sense amplifier activating signal terminal 15".

The external sense amplifier activating signal that is input to theexternal sense amplifier activating signal terminal may be input from asuitable external circuit or may be the one that is generated insynchronism with the /RAS signal. Or, the /RAS signal may be directlyutilized.

According to the present invention, the external sense amplifieractivating signal behaves in the selected bank differently from theactivation or the de-activation of the /RAS signal and Maintains thesense amplifier in the active condition even when the word line (WL) isde-activated. Thus, the sense amplifier in the bank is maintainedactivated independently of the /RAS signal.

Though the above description has dealt with the sense amplifier controlcircuit 10 in which the two banks are constituted by dividing the memorycells into two regions, it should be noted that the invention is in noway limited to the above embodiment only but encompasses the cases wherethe memory cells are divided into a plurality of regions greater thantwo to constitute banks of a number of greater than two. It need not bepointed out that in these cases, the aforementioned constituent elementssuch as the sense amplifier control signal-generating means 5, externalsense amplifier activating signals, sense amplifier drivesignal-generating means 7, bit line-resetting means 6 and the like areprovided in a number that corresponds to the number of the banks.

In the sense amplifier control circuit 10 according to the presentinvention, there are provided a plurality of banks which are constitutedby a plurality of memory blocks of, for example, 256 k, and any one ofthem is selected by the external bank signal and is activated by apredetermined logic and the external sense amplifier activating signal.

In the present invention, the bank is selected, and the predetermineddata are stored, held, calculated and transmitted as a group.

Described below with reference to a block diagram of FIG. 3 is theconcrete constitution of the RAS first-stage circuit 13 in the senseamplifier control circuit 10 according to the first embodiment of thepresent invention.

That is, the RAS input first-stage circuit 1 which inputs the /RASsignal outputs an address latch signal ADLCH and an address activatingsignal ADAS which are then input to the row address buffer circuit 27that is receiving the external bank signal.

On the other hand, the address activating signal ADAS output from theRAS input first-stage circuit is input to a precharge signal-generatingcircuit 22 and to a word driver generating circuit 24 whose outputs areinput to a preword driver generating circuit 23.

To the precharge signal-generating circuit 22 is also fed an output of aword line boost generating circuit 2 which will be described later. Aprecharge signal PRCHS is output from the precharge signal-generatingcircuit 22 based upon the logic of the address activating signal ADASand the output of the word line boost generating circuit 2.

The row address buffer circuit 27 outputs bank address complementarysignals BADCOMS (e.g., BNKX, BNKZ, etc.) which are fed to the rowpredecoder 21 and to the plurality of block select decoders 26,respectively. The precharge signal PRCHS output from the prechargesignal generating circuit 22 is also input to the row predecoder 21 andto the block select decoder 26.

As a result, the row predecoder 21 outputs a predecoder address signalPRDADD to the main row decoder 8 which then outputs a word line (WL)activating signal. Then, the block select decoders 26 output blockselect signals BLCSS which are fed to the main row decoder 8.

On the other hand, the preword driver generating circuit 23 outputs apreword driver signal PRWDS which is input to the above-mentioned wordline boost generating circuit 2.

In response to the preword driver signal PRWDS, the word line boostgenerating circuit 2 outputs a word line boost signal WLBST which isinput to the precharge signal generating circuit 22 as described aboveand is, at the same time, input to the row predecoder circuit 3. Theoutput of the row predecoder circuit 3 is input to the main row decoder8.

Provision is further made of a row decoder reset generating circuit 25which receives the precharge signal PRCHS output from the prechargesignal-generating circuit 22, the address activating signal ADAS and theword line boost signal WLSBT. The row decoder reset signal RDCRST outputfrom the row decoder reset generating circuit 25 is input to the mainrow decoder 8.

The block select signals BLCSS output from the block select decoders 26are fed to the sense amplifier control signal-generating means 5.

FIG. 4 is a block diagram which illustrates the concrete constitution ofthe sense amplifier control signal-generating means 5 according to thefirst embodiment of the present invention, wherein the circuitsconstituting the sense amplifier control signal-generating means 5 areeach provided in a plurality of numbers to correspond to the number ofthe banks.

First, the external sense amplifier activating signal is input to asense amplifier enable buffer 31 to generate a sense amplifieractivating signal SAAS which is then input to the sense amplifier enablegenerating circuit 32.

The sense amplifier enable generating circuit 32 further receives blockselect signals BLCSS output from the block select decoders 26 and theword line boost signal WLBST.

The sense amplifier enable generating circuit 32 sends an output thatresponds to the input signals having a certain logic, to a timing wordline generating circuit 33 which then sends an output to a prelatchenable generating circuit 34.

The prelatch enable generating circuit 34 further receives the senseamplifier activating signal SAAS output from the sense amplifier enablebuffer 31, and outputs a prelatch enable signal PRLACHE in response tothe logic of the above two signals. The prelatch enable signal PRLACHEis input to the sense amplifier driver generating circuit 36. The otheroutput of the prelatch enable generating circuit 34 is input to a bitline resent generating circuit 35 which outputs a bit line reset signalBTRST that will be input to the sense amplifier driver generatingcircuit 36.

As a result, the sense amplifier driver generating circuit 36 outputs asense amplifier driver signal (for N channel), a sense amplifier driversignal (for P channel and a latch enable signal LACHE. The latch enablesignal LACHE is input to the sense amplifier driver generating circuit37 which outputs a sense amplifier driver signal (for P channel).

Operation of the sense amplifier control circuit 10 according to thefirst embodiment of the present invention will now be described withreference to FIG. 5.

FIGS. 5A-5F are diagrams of waveforms for explaining the drivingcondition of the major portion of the sense amplifier control circuit 10of the present invention, wherein in response to the fall of the /RASsignal (activation of /RAS signal), the external bank signal reads andlatches an address n for selecting a predetermined bank.

A specified bank is selected in response to the latched data and data ofthis bank only is read out.

In other banks, the data selected at a previous moment are held.

As the external sense amplifier activating signal terminal 15 rises insynchronism with the fall of the /RAS signal, furthermore, the bit linereset signal resets a bit line that corresponds to the bank.

On the other hand, the word line (WL) is raised after a predetermineddelay time after the fall of the /RAS signal prior to receiving theinternal sense amplifier activating signal, i.e., prior to receiving theoutput of the sense amplifier control signal-generating means 5.

Here, the internal sense amplifier activating signal is raised basedupon the logic of the /RAS signal and the external sense amplifieractivating signal.

Therefore, even when the /RAS signal rises and the word line (WL) isde-activated in synchronism therewith, the internal sense amplifieractivating signal holds the active condition.

Then, when the same external bank signal is selected and is latched insynchronism with the break of the /RAS signal, the predetermined datacan be read out while making access to the column address since theinternal sense amplifier activating signal has already been activated atthe moment when the word line (WL) is raised.

That is, in this embodiment, the word line (WL) is activated by the fallof the /RAS signal. As the word line (WL) is activated by the logic ofthe external sense amplifier activating signal and the external banksignal, the internal sense amplifier activating signal is activated andthe sense amplifier operates.

On the other hand, the word line (WL) is de-activated and is reset atthe rise of the /RAS signal. When the external sense amplifieractivating signal is in the active condition, however, the internalsense amplifier activating signal stores the data in the bit line, andthe sense amplifier continues its operation.

Furthermore, the internal sense amplifier activating signal isde-activated after a predetermined delay time has passed from when theword line (WL) is de-activated at the rise of the /RAS signal and theexternal sense amplifier activating signal is de-activated.

Thus, the data can be held by the sense amplifier even when the wordline (WL) is reset. Therefore, once access is made, the data is alreadyheld in the sense amplifier. Therefore, when the same address (word line(WL)) is to be selected next time, access needs simply be made to thecolumn address contributing greatly to decreasing the access time.

In this case, a control circuit must be separately provided to comparethe row addresses.

According to the embodiment of the present invention, furthermore, theperiod for activating the sense amplifier can be lengthened up to a timefor refreshing the DRAM, i.e., up to a time necessary for refreshing allof the cells making it possible to impart a considerable margin to theaccess time.

According to the prior art, the sense amplifier could be activated onlyduring the period in which the word line (WL) is raised. During theperiod in which the word line (WL) is raised, furthermore, the senseamplifier could usually be activated for a period of time shorter thanthe time for refreshing the cells, and access could be made for a shortperiod of time.

According to the present invention, the period for activating the senseamplifier is lengthened to be equal to the refresh time. Therefore, thetime in which access can be made is lengthened to about 160 times aslong as the conventional time making it possible to effect an accessmaintaining margin.

The data are erased during the refreshing time. During this period,therefore, it is not allowed to make access to the column address.According to the present invention, however, the time for making accessis increased and the refreshing time is decreased to a time interval asshort as possible, so that the access operation can be reliablyexecuted.

Described below is the sense amplifier control circuit according to asecond embodiment of the present invention.

In the sense amplifier control circuit 10 according to the firstembodiment of the present invention, an external sense amplifieractivating signal is used to control the sense amplifier. According tothe present invention, however, it is also allowable to control thebanks by forming the /RAS signals in a plurality of numbers thatcorrespond to the number of the banks and by selectively using them,instead of using the external sense amplifier activating signal.

That is, as shown in the block diagrams of FIGS. 6 and 7, the secondembodiment of the present invention is concerned with a sense amplifiercontrol circuit 50 in a dynamic random access memory (DRAM) whichcomprises at least a memory cell means 11, sense amplifiers 12, a /RASsignal input means 1, a word line (WL) boost signal-generating means 2,a sense amplifier control signal-generating means 5 and a senseamplifier drive signal-generating means 7, in order to read cell data byactivating the word lines (WL) by utilizing row address strobe (/RAS)signals, wherein said memory cell means 11 is constituted by a pluralityof banks 11', 11", said sense amplifiers are provided in a plurality ofnumbers 12', 12", said sense amplifier control signal-generating means 5are provided as a plurality of such elements 5', 5" to correspond to theplurality of banks 11', 11", said /RAS signals are formed in a pluralityof numbers (/RAS (A) signals and /RAS (B) signal) to correspond to theplurality of banks 11', 11", and said word line (WL) boostsignal-generating means 2 is so constituted as to activate the wordlines (WL) by a one shot pulse in synchronism with the rising andfalling edges of the /RAS signals (/RAS (A) signal and /RAS (B) signal).

That is, this embodiment employs the circuit constitution of differentclock CLK signal systems, i.e., the (A) clock system and the (B) clocksystem, the constitution comprising the sense amplifier controlsignal-generating circuit 5', sense amplifier drive circuit 7' and bitline reset generating circuit 6' that are controlled by the /RAS (A)signal, and the sense amplifier control signal-generating circuit 5",sense amplifier drive circuit 7" and bit line reset generating circuit6" that are controlled by the /RAS (B) signal, and between which areprovided the RAS first-stage circuit 1 that receive the /RAS (A) signaland the /RAS (B) signal in common, the word line (WL) boostsignal-generating means 2 connected in series therewith and the wordline (WL) predecoder circuit 3, the output of the word line (WL)predecoder circuit 3 being connected to the word line (WL) main decodercircuit 4' that is controlled by the /RAS (A) signal to control the wordline (WL) (A) and to the word line (WL) main decoder circuit 4" that iscontrolled by the /RAS (B) signal to control the word line (WL) (B).

In the sense amplifier control circuit 50 according to the secondembodiment of the present invention, as will be understood from FIG. 7,the column address control circuit 16 is provided separately from the/RAS signal system, the column address control circuit 16 including acolumn address signal input means 17, and a suitable input/outputcircuit (I/0 circuit) 18.

That is, the sense amplifier control circuit 10 according to the presentinvention is constituted, as shown in FIG. 7, by the RAS circuit 20, thememory circuit 11 made up of a plurality of banks 11', 11" and senseamplifiers 12', 12" corresponding to the banks 11', 11", and the columnaddress control circuit 16. Moreover, the RAS circuit 20 is constitutedby the RAS first-stage circuit 13, first sense amplifier controlsignal-generating circuit 5', second sense amplifier controlsignal-generating circuit 5", first row decoder 8' that controls thefirst bank 11', first sense amplifier drive signal-generating circuit 7'that controls the first sense amplifier 12', second row decoder 8" thatcontrols the second bank 11" and second sense amplifier drivesignal-generating circuit 7" that controls the second sense amplifier12".

The RAS first-stage circuit 13 in the sense amplifier control circuit 50according to the second embodiment of the present invention includes aRAS signal first-stage input circuit 1 which receives different /RASsignals which are row address signals (referred to as /RAS (A) signaland /RAS (S) signal) for selecting the data that correspond to differentbanks, and further has a separate external bank signal row address inputterminal 14 that determines which one should be selected out of theplurality of banks. The output of the external bank signal row addressinput circuit 14 and the output of the RAS signal first-stage inputcircuit 1 are input to the row address buffer 27 which outputspredetermined internal bank signals BNKX and BNKZ that will beseparately input to the first and second sense amplifier controlsignal-generating means 5' and 5".

Other circuits, their connections and their functions are nearly thesame as those of FIG. 1, and are not described here in detail.

FIGS. 8A-8H are diagrams of waveformes for explaining the drivingcondition of the major portion of the sense amplifier control circuit 50according to the above-mentioned embodiment, wherein a specified bank isselected in response to the fall of the /RAS (A) signal (activation ofthe /RAS (A) signal), the word line (WL) (A) corresponding to theselected bank is activated by one shot pulse and, at the same time, abit line reset signal (A) is output in synchronism with the break of the/RAS (A) signal in order to reset the bit line (A) that corresponds tothe bank.

On the other hand, the internal sense amplifier activating signal (A) isactivated, i.e., the sense amplifier control signal-generating means 5'is activated after a predetermined delay time has passed from when theword line (WL)(A) is activated, in synchronism with the break of the/RAS signal.

The internal sense amplifier activating signal is raised based on thelogic of the /RAS signal and the external sense amplifier activatingsignal as in the first embodiment.

Therefore, even when the /RAS signal is raised and the word line (WL) isde-activated in synchronism therewith, the internal sense amplifieractivating signal remains in the active condition.

Then, in synchronism with the break of the /RAS (A) signal, the wordline (WL) (A) is activated again by the one shot pulse. The internalsense amplifier activating signal is de-activated after a predetermineddelay time has passed from the break of the one shot pulse. During theperiod in which the internal sense amplifier activating signal isactivated, the data read out from the predetermined bank is stored inthe sense amplifier.

On the other hand, the specified bank is selected in response to thebreak of another /RAS (B) signal (activation of the /RAS (B) signal),and the word line (WL) (B) corresponding to the selected bank isactivated by the one shot pulse and, at the same time, the bit linereset signal (B) is output in synchronism with the break of the /RAS (B)signal to reset the bit line (B) that corresponds to the bank.

On the other hand, the internal sense amplifier activating signal (B) isactivated, i.e., the sense amplifier control signal-generating means 5"is activated after a predetermined delay time has passed from when theword line (WL) (B) is activated, in synchronism with the fall of the/RAS signal.

Then, in synchronism with the fall of the /RAS (B) signal, the word line(WL) (B) is activated again by the one shot pulse, and the internalsense amplifier activating signal is de-activated after a predetermineddelay time has passed from the fall of the one shot pulse. Here, duringthe period in which the internal sense amplifier activating signal isactivated, the data read from the predetermined bank is held by thesense amplifier.

That is, in this embodiment, the word line (WL) (A) of the block (A) isactivated at the fall of the /RAS (A) signal, and the sense amplifier ofthe block (A) is activated upon receipt of a logic of the /RAS (A)signal and the word line (WL) (A).

Similarly, the word line (WL) (B) of the block (B) is activated at thefall of the /RAS (B) signal, and the sense amplifier of the block (B) isactivated in response to a logic caused by the /RAS (B) signal and theword line (WL) (B).

This constitution makes it possible to effect access to the block (B)while the sense amplifier in the block (A) is being activated. When itis attempted to effect access to the same row address (word line (WL))of the block (A), the data is already held in the sense amplifier makingit possible to shorten the access time.

The sense amplifier control circuit 60 according to a third embodimentof the present invention will be described next.

In the sense amplifier control circuits 10 and 50 of the aforementionedfirst and second embodiments, the bank including the sense amplifier iscontrolled by using the external bank signal or a plurality of /RASsignals. The present invention, however, is in no way limited to suchembodiments only but also makes it possible to control the banks relyingupon the bank addresses only as a method of controlling the senseamplifier.

This embodiment will now be described with reference to FIGS. 9 and 10.

As shown in the block diagrams in FIGS. 9 and 10, the third embodimentof the present invention is concerned with a sense amplifier controlcircuit 60 in a dynamic random access memory (DRAM) which comprises atleast a memory cell means 11, sense amplifiers 12, a /RAS signal inputmeans 1, a word line (WL) boost signal-generating means 2, a senseamplifier control signal-generating means 5 and a sense amplifier drivesignal-generating means 7 in order to read cell data by activating theword lines (WL) by utilizing row address strobe (/RAS) signals, whereinsaid memory cell means 11 is constituted by a plurality of banks 11',11", said sense amplifiers are provided in a plurality of numbers 12',12", said sense amplifier control signal-generating means 5 are providedin a plurality of numbers 5', 5" to correspond to the plurality of banks11', 11', said word line (WL) boost signal-generating means 2 is soconstituted as to activate the word lines (WL) by one shot pulse insynchronism with the rising and falling edges of the /RAS signals, andsaid sense amplifier control signal-generating means 5 are soconstituted as to activate the sense amplifiers in synchronism with bankaddress signals that are derived from said /RAS signals.

In this embodiment, the word line (WL) rises and falls in response tothe /RAS signals in the same manner as the activation and de-activationoperations of the word line (WL) in the first embodiment shown inFIG. 1. Unlike the operation of FIG. 1, however, the sense amplifier isactivated and de-activated by utilizing the /RAS signal and the externalbank address.

FIGS. 9 and 10 are block diagrams illustrating the constitution of thesense amplifier control circuit 60 according to the third embodiment ofthe present invention in a dynamic random access memory (DRAM) whichcomprises at least a memory cell means 11, sense amplifiers 12, a /RASsignal input means 1, a word line (WL) boost signal-generating means 2,a sense amplifier control signal-generating means 5 and a senseamplifier drive signal-generating means 7, in order to read cell data byactivating the word lines (WL) by utilizing row address strobe (/RAS)signals, wherein said memory cell means 11 is constituted by a pluralityof banks 11', 11", said sense amplifiers are provided in a plurality ofnumbers 12', 12" to correspond thereto, said sense amplifier controlsignal-generating means 5 are provided in a plurality of numbers 5', 5"to correspond to the plurality of banks 11', 11", and provision is madeof external sense amplifiers which are connected to said sense amplifiercontrol signal-generating means 5', 5" in order to activate the senseamplifiers 12', 12" independently of the /RAS signals.

FIG. 9 is a block diagram illustrating the constitution of the senseamplifier control circuit 60 according to the present invention, whereinthe same constituent elements as those of FIG. 12 are denoted by thesame reference numerals as those of FIG. 12.

FIG. 10 is a block diagram which schematically illustrates the wholesystem constitution of the sense amplifier control circuit 60 accordingto the third embodiment of the present invention that is shown in FIG.9.

As will be understood from FIG. 10, the sense amplifier control circuit60 according to the third embodiment of the present invention isprovided with the same column address control circuit 16 as that of FIG.2.

The sense amplifier control circuit 60 according to the presentinvention is constituted, as shown in FIGS. 9 and 10, by the RAS circuit20, the memory circuit 11 made up of a plurality of banks 11', 11" andsense amplifiers 12', 12" corresponding to the banks 11', 11", and thecolumn address control circuit 16. Moreover, the RAS circuit 20 isconstituted by the RAS first-stage circuit 13, first sense amplifiercontrol signal-generating circuit 5', second sense amplifier controlsignal-generating circuit 5", first row decoder 8' that controls thefirst bank 11', first sense amplifier drive signal-generating circuit 7'that controls the first sense amplifier 12', second row decoder 8" thatcontrols the second bank 11" and second sense amplifier drivesignal-generating circuit 7" that controls the second sense amplifier12".

The RAS first-stage circuit 13 in the sense amplifier control circuit 60according to the third embodiment of the present invention includes aRAS signal first-stage input circuit 1 as the /RAS signal input means 1.Further, the external bank signal row address that determines which oneshould be selected out of the plurality of banks and the output of theRAS signal first-stage input circuit 1 are input to the row addressbuffer 27 which outputs predetermined internal bank signals BNKX andBNKZ that will be separately input to the first and second senseamplifier control signal-generating means 5' and 5".

The external bank signal according to the present invention is anaddress signal of the bank which may be the same as the /RAS signal.

According to the third embodiment of the present invention, the senseamplifier control signal-generating means 5 are provided in a numberthat corresponds to the number of the banks as in the aforementionedembodiments. That is, in this embodiment which has two banks, there areprovided the first and the second sense amplifier controlsignal-generating means 5', 5" as shown in FIGS. 9 and 10.

The first and the second sense amplifier control signal-generating means5', 5" include a suitable one shot pulse-generating means.

Then, the first and second sense amplifier drive signal-generating means7', 7" are selected in order that the predetermined bank is activated bythe sense amplifier control signal-generating means 5', 5" in responseto the above-mentioned predetermined internal bank signal BNKX, BNKZ anda bank address formed by the /RAS signal.

Operation of the sense amplifier control circuit 60 according to thethird embodiment of the present invention will now be described withreference to the waveform diagrams of FIGS. 11A-11J.

Referring first to FIGS. 11A-11J, n and m of the bank select signals maybe addresses representing different banks or may be different chips.

The word line (WL) n0 is part of the word line in a bank n, and the wordline (WL) n1 is part of the other word line (WL) in the same bank n.

Similarly, the word line (WL) m0 is part of the word line (WL) in a bankm, and the word line (WL) m1 is part of the other word line (WL) in thesame bank m.

Under such a condition, a predetermined word line (WL) n0 in theselected bank is activated by one shot pulse due to the rise of the /RASsignal and, at this time, the internal sense amplifier activating signaln is activated upon receipt of the external bank n address signal andthe rise of the word line (WL).

Owing to the provision of the bank address latch circuit, the internalsense amplifier activating signal n maintains the active condition evenwhen the word line (WL) that is generated by one shot pulse isde-activated, and, hence, the data is held by the sense amplifier.

The word line (WL) is activated again by the one shot pulse incompliance with an address due to the rise of the /RAS signal. Upon therise of the word line (WL) and the external bank m address, the internalsense amplifier activating signal m is de-activated and the senseamplifier is reset.

Describing the embodiment in further detail, when the rising /RAS signaland a bank select signal of the external bank signal have selected, forexample, n of the bank so that the row address is n0, the word line (WL)n0 of the bank n rises and is then permitted to fall after the passageof a predetermined period to perform a one-shot pulse operation.

Such an operation is called restoration (rewriting). Though the data hasbeen input to the sense amplifier in this stage, the word line (WL) hasnot yet been activated and no data is written onto the cell.

An operation is therefore necessary to write the data onto the cell fromthe sense amplifier by activating the word line (WL). Theabove-mentioned operation is intended to execute this operation.

The sense amplifier activating signal n of the bank n is de-activated inresponse to the fall of the one-shot pulse on the word line (WL) n0 inthe bank n, and the condition is established to read the word line (WL).

Then, as the /RAS signal falls, the other word line (WL) n1 is selectedin the bank n, when the address is n1, in the condition where the bankselect signal is still specifying the bank n. Therefore, the word line(WL) n1 performs a one-shot pulse operation and the data of the wordline (WL) n1 is read out.

The sense amplifier activating signal n of the bank n is activated aftera predetermined delay time from the rise of the word line (WL) n1, andthe data that is read out is held in the sense amplifier.

On the other hand, a bit line of the bank n is activated by the one-shotpulse operation when the sense amplifier activating signal n of the bankn is de-activated before the word line (WL) n1 performs the one-shotpulse operation. Thus, a predetermined bit line is reset.

That is, in this embodiment, the word line (WL) is activated by theone-shot pulse operation either when the /RAS signal is raised orfallen.

The same operation is executed for bank m. That is, when the bank selectsignal is specifying the bank m when the /RAS signal rises and when theaddress is specifying the word line (WL) m0, the word line (WL) m0 ofthe bank m is restored. Next, when the bank select signal is stillspecifying the bank m when the /RAS signal falls and when the address isspecifying the word line (WL) m1, the word line (WL) m1 is selected andperforms a one-shot pulse operation. At the same time, the data of theword line (WL) m1 is read out.

The other waveforms are the same as those in the case of bank n and arenot described here.

In the sense amplifier control circuit in a DRAM which employs a banksystem using a plurality of banks according to the present invention asdescribed above, a circuit for activating the word lines (WL) in theDRAM is commonly used, and the word line (WL) activating function andthe sense amplifier activating function are so constituted that they canbe driven independently of each other. Therefore, the sense amplifieractivating function is activated without being controlled by apredetermined /RAS signal and, as required, the sense amplifieractivating function is maintained in the activated condition to hold thenecessary data. When the same data or the data having a predeterminedrelationship to the above data are to be read out, the time forexecuting the arithmetic processing can be greatly shortened.

According to the present invention which uses a plurality of banks,furthermore, it is allowed to maintain a bank activated, i.e., tomaintain predetermined data while exchanging data to other banks. It isfurther allowed to extend the period for activating the sense amplifiersup to a period which is equal to a maximum refreshing time in the DRAM,giving a margin to the arithmetic processing operation.

That is, according to the present invention, the word line (WL)activating function and the sense amplifier activating function workindependently from each other in a DRAM having a plurality of banks suchas in a Rambus DRAM in order to extend the sense amplifier active periodup to the refresh time. Moreover, a single word line (WL) activatingcircuit is employed for the plurality of banks in order to executeaccess at high speeds.

FIGS. 14 to 16 illustrate the system constitutions according to thefirst to third embodiments of the present invention, wherein FIG. 14illustrates the system constitution according to the above-mentionedfirst embodiment.

In the drawings, there are provided a plurality of devices or chips 1 ton, each of the devices or the chips being provided with two banks.

A predetermined bank is selected by the /RAS signal and the bankaddress, the word line (WL) in the selected bank is activated, and thesense amplifier is activated by an external sense amplifier activatingsignal.

FIG. 15 illustrates the system constitution according to the secondembodiment which controls the bank relying upon a plurality of /RASsignals.

In the drawing, there are provided a plurality of devices or chips 1 ton, each of the devices or the chips being provided with two banks.

A predetermined bank is selected by a plurality of /RAS signals and by abank address, and the word line (WL) in the selected bank is activatedto activate the sense amplifier.

FIG. 16 illustrates the system constitution according to the thirdembodiment which controls the bank using a bank address only.

In the drawing, there are provided a plurality of devices or chips 1 ton, each of the devices or the chips being provided with two banks.

A predetermined bank is selected by a /RAS signal and a bank address,and the word line (WL) in the selected bank is activated to activate thesense amplifier.

We claim:
 1. A dynamic random access memory (DRAM) comprising:aplurality of memory cells selected by word lines and bit lines; senseamplifiers connected to each one of said bit lines; a word line (WL)boost signal-generating circuit activating at least one of said wordlines by a one shot pulse in synchronism with the rising and breakingedges of each one of a plurality of row address strobe (/RAS) signals;and a sense amplifier control signal-generating circuit controlling saidsense amplifiers so as to activate or deactivate said sense amplifier ina synchronism with said row address strobe (/RAS) signals.
 2. A dynamicrandom access memory (DRAM) according to claim 1, wherein each one ofsaid plurality of memory cells has a plurality of banks.
 3. A dynamicrandom access memory (DRAM) according to claim 2, wherein said pluralityof row address strobe (/RAS) signals are assigned to correspond to thenumber of said banks.
 4. A dynamic random access memory (DRAM) accordingto claim 3, wherein one of said plurality of row address strobe (/RAS)signals maintains said sense amplifier in an active condition whenanother row address strobe (/RAS) signal is deactivated.
 5. In a dynamicrandom access memory (DRAM) which comprises at least a memory cellmeans, sense amplifiers coupled to said memory cell means, a row addressstrobe signal (/RAS) input means, a word line (WL) boostsignal-generating means a sense amplifier control signal-generatingmeans and a sense amplifier drive signal-generating means coupled tosaid sense amplifiers reading cell data by activating the word line (WL)by utilizing the row address strobe signal, wherein said memory cellmeans is constituted by a plurality of banks, said sense amplifiercontrol signal-generating means are provided in a plurality of numbersto correspond to the plurality of banks, row address strobe signals areformed in plurality of numbers to correspond to the plurality of banks,said word line (WL) boost signal-generating means activates the wordlines (WL) by a one shot pulse in synchronism with the rising andbreaking edges of the row address strobe signals, and said senseamplifier control signal-generating means activates the sense amplifiersin synchronism with the row address strobe signals.